CALCULATION OF THERMODYNAMIC AND KINETIC PARAMETERS OF CATALYTIC CRACKING REACTIONS ON LEWIS AND BRØNSTED ACID SITES

IF 0.6 Q4 ENGINEERING, GEOLOGICAL
G. Nazarova, E. Ivashkina, V. V. Maltsev
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引用次数: 0

Abstract

Link for citation: Nazarova G.Y., Ivashkina E.N., Maltsev V.V. Calculation of thermodynamic and kinetic parameters of catalytic cracking reactions on Lewis and Brønsted acid sites. Bulletin of the Tomsk Polytechnic University. Geo Аssets Engineering, 2023, vol. 334, no. 7, рр. 214-225. In Rus. The relevance of the research is caused by the emerging necessity of developing a mathematical model to optimize the heterogeneous process of catalytic cracking. This tools should take into account both the chemical transformations of a wide range of hydrocarbon groups (different feedstock types), as well as the stages of adsorption, reactants diffusion, conversion of hydrocarbons on the catalyst surface, acid characteristics and pore size of the catalysts. The study of the hydrocarbon conversion patterns on Lewis or Brønsted acid sites using quantum-chemical modeling methods allow us to quantify the thermodynamic parameters of reactants adsorption, the kinetic parameters of carbocations formation and cracking on acid sites. These results are necessary to develop a mathematical model based on the of heterogeneous catalytic reaction mechanism. The aim of this work is to identify the level of quantum chemical theory and to determine the thermodynamic and kinetic parameters of reactants adsorption, carbenium ions formationand hydrocarbons cracking on Lewis and Brønsted acid sites. Methods: quantum-chemical modeling methods to optimize the molecular geometry of reactants and products of catalytic cracking reactions, calculate vibrational frequencies, thermodynamic parameters of adsorption and catalytic cracking of hydrocarbons and heteroatomic compounds with the participation of Bronsted and Lewis acid sites. Results. The chosen level of quantum-chemical theory allowed obtaining the results that are consistent with the laws of the process and the experimental reactivity of hydrocarbons in cracking reactions on acid catalysts. The thermodynamic parameters of the adsorption of C6–C16 hydrocarbons and thiophenes on Lewis and Brønsted acid sites were identified. We found that during the cracking of n-hexane on the Lewis acid site, the reaction is limited by the carbenium ion formation stage.The activation energy of this stage was 281,3 kJ/mol whereas the value for the cracking stage was 277,2 kJ/mol. Further study shows that the activation energy of carbenium ion formation from izohexane and C8–C10 alkanes with normal structure on the Lewis acid site was 257,6 and 279,2…277,9 kJ/mol. The most energetically favorable is the formation of carbocation from hexene at Brønsted acid sites (76,59 kJ/mol). The results of the work will be used to create a mathematical model of a heterogeneous process based on the Langmuir–Hinshelwood equations.
lewis和brØnsted酸位催化裂化反应热力学和动力学参数的计算
引用本文链接:Nazarova G.Y, Ivashkina E.N., Maltsev V.V.。Lewis和Brønsted酸位点催化裂化反应热力学和动力学参数的计算。托木斯克理工大学公报。岩土工程Аssets, 2023,第334卷,第2期。7,рр。214 - 225。俄文。研究的相关性是由于迫切需要建立数学模型来优化催化裂化的非均相过程。该工具应考虑各种烃类(不同的原料类型)的化学转化,以及吸附、反应物扩散、催化剂表面烃类转化的阶段、催化剂的酸性特征和孔径。利用量子化学建模方法对Lewis或Brønsted酸位上烃类转化模式的研究,使我们能够量化反应物吸附的热力学参数、酸位上碳阳离子形成和裂解的动力学参数。这些结果为建立基于非均相催化反应机理的数学模型提供了依据。这项工作的目的是确定量子化学理论的水平,并确定Lewis和Brønsted酸位点上反应物吸附、碳离子形成和碳氢化合物裂解的热力学和动力学参数。方法:采用量子化学建模方法优化催化裂化反应的反应物和产物的分子几何结构,计算Bronsted和Lewis酸位参与下烃类和杂原子化合物吸附和催化裂化的振动频率、热力学参数。结果。所选择的量子化学理论水平使得得到的结果与过程规律和酸催化剂上烃类裂解反应的实验反应性相一致。确定了C6-C16碳氢化合物和噻吩在Lewis和Brønsted酸位点上的吸附热力学参数。研究发现,正己烷在Lewis酸位点裂解过程中,反应受到碳离子形成阶段的限制。该阶段的活化能为281,3 kJ/mol,而裂解阶段的活化能为277,2 kJ/mol。进一步研究表明,异己烷和正构C8-C10烷烃在Lewis酸位上生成正碳离子的活化能分别为257、6和279、2和277、9 kJ/mol。能量上最有利的是在Brønsted酸位上由己烯形成碳正离子(76,59 kJ/mol)。这项工作的结果将用于建立一个基于Langmuir-Hinshelwood方程的异构过程的数学模型。
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来源期刊
CiteScore
1.40
自引率
50.00%
发文量
210
审稿时长
5 weeks
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